A new MspI restriction fragment length polymorphism in the hemophilia B locus

Polymorphisms associated with the FVIII and FIX genes in the Turkish population

In order to determine the gene frequencies of nine polymorphic sites associated with FVIII and FIX genes in the Turkish population a sample of 50-235 unrelated X chromosomes from healthy individuals were analysed by using PCR-based assays. The Turkish population was found to be as polymorphic as Europeans in the FVII and FIX genes. Analysis of FIX haplotypes revealed that the most frequent haplotype observed in European populations and Anglo-Americans was also very common among Turks. The present population-based study indicates that two marker loci, namely HindIII and St14 in the factor VIII gene and DdeI and HhaI in the factor IX gene, are highly informative and useful markers that can be used in DNA linkage analysis for the assessment of haemophilia carriers and affected fetuses in the Turkish population.

Interlocus non-random association of multiallelic polymorphisms spanning the coagulation factor VIII gene on human chromosome distalmost Xq28

The most common severe hereditary bleeding disorder phenotype in humans, the coagulation factor VIII (F8) deficiency haemophilia A (HEMA), maps on Xq28 band, a region that comprises 11.7% of genes and 14.2% of phenotypes on X chromosome. Information about the distribution and extent of gametic disequilibrium (GD) covering the F8 gene is scarce, despite its relevance for linkage and association studies. The aim of this study was to determine the patterns, by frequency and strength, of non-random multiallelic interallelic associations between two-locus combinations of seven microsatellite loci (REN90833, F8Int25.2, F8Int22, F8Int13.2, HEMA154311.3, TMLHEInt5 and HEMA154507.3, in that physical order) spanning 0.813 Mb on distalmost Xq28. We measured sign-based interallelic D' coefficients in 106 men and in 100 women drawn from a single unrelated Brazilian population. Significance and patterns of GD using haploid and phased diploid sample probabilities were close to conformity. Only 9.18% of the variance of D' could be accounted for by changes in length, indicating that GD is not a monotonically decreasing function of length. We defined two regions of overlapping long-range GD extending 698 735 base pairs (bp) (REN90833/TMLHEInt5 block) and 689 900 bp (F8Int13.2/HEMA154507.3 block) The extent of GD overlap is 575 637 bp (F8Int13.2/TMLHEInt5 interstice). Extended haplotype homozygosity analysis centred at the F8 intronic loci revealed that the most frequent core haplotypes decay the least in the flanking GD. The F8 intronic loci attend distinct non-random association forces; F8Int13.2 serves at maintenance of the long-range overlapping pattern of GD, whereas F8Int25.2 and F8Int22 serve at lessening it in force or effect.

Why does the mutation G17736A/Val107Val (silent) in the F9 gene cause mild haemophilia B in five Swedish families?

The mutation G17736A/Val107Val (silent) was found in five of a total of 86 families with haemophilia B in Sweden. It is unlikely that five families with analogous clinical expression will have the same polymorphism, which is not found in other patients or normal subjects, or that they will be the only families in the population without any other causative mutation. All affected individuals in the five families were found to have factor IX (F9) coagulation activity 15-20 U dL(-1), corresponding F9 protein levels and the same clinical history of mild haemophilia. Lymphocyte mRNA was extracted from one of the haemophiliacs and from a healthy male. RT-PCR of the mRNA and subsequent PCR amplification produced cDNA fragments of the same length from the patient and the normal subject, indicating no exon skipping or retention of introns. Sequencing of cDNA from codon 68 in exon D to codon 180 in exon F revealed that the patient had the G17736A mutation but no other abnormalities. We conclude that G17736A/Val107Val causes mild haemophilia B. Although, exon skipping and retention of introns can be excluded as pathophysiological mechanisms, it is plausible that the studied mutation has more subtle effects on a splicing site or interferes with a splicing enhancer site. Also, changes to synonymous codons may reduce the translation rate and thereby alter F9 protein folding in vivo, which would explain the phenotype. Confirmation of these assumptions requires methods that are more sensitive than those available today, and our discussion illustrates the existing obstacles.

Haemophilia A and haemophilia B: molecular insights

This review focuses on selected areas that should interest both the scientist and the clinician alike: polymorphisms within the factor VIII and factor IX genes, their linkage, and their ethnic variation; a general assessment of mutations within both genes and a detailed inspection of the molecular pathology of certain mutations to illustrate the diverse cause-effect relations that exist; a summary of current knowledge on molecular aspects of inhibitor production; and an introduction to the new areas of factor VIII and factor IX catabolism. An appendix defining various terms encountered in the molecular genetics of the haemophilias is included, together with an appendix providing accession numbers and locus identification links for accessing gene and sequence information in the international nucleic acid databases.

Haemophilia A and haemophilia B: molecular insights

This review focuses on selected areas that should interest both the scientist and the clinician alike: polymorphisms within the factor VIII and factor IX genes, their linkage, and their ethnic variation; a general assessment of mutations within both genes and a detailed inspection of the molecular pathology of certain mutations to illustrate the diverse cause-effect relations that exist; a summary of current knowledge on molecular aspects of inhibitor production; and an introduction to the new areas of factor VIII and factor IX catabolism. An appendix defining various terms encountered in the molecular genetics of the haemophilias is included, together with an appendix providing accession numbers and locus identification links for accessing gene and sequence information in the international nucleic acid databases.

Haemophilia B mutations in Sweden: a population-based study of mutational heterogeneity

The present series comprises all families (n = 77) with haemophilia B in Sweden and may be considered to be representative for the purposes of a population-based study of mutational heterogeneity. The 77 families (38 severe, 10 moderate, 29 mild) had 51 different mutations in total. Thirteen families had total, partial or small deletions, two had mutations in the promoter, eight families had splice site mutations, 14 had nonsense and the remaining 41 had missense mutations. Ten of the mutations, all C-->T or G-->A, recurred in 1--6 other families. Using haplotype analysis of seven polymorphisms in the factor IX (FIX) gene, we found that the 77 families carried 65 unique, independent mutations. Of the 48 families with severe or moderate haemophilia, 23 (48%) had a sporadic case of haemophilia compared with 31 families out of 78 (40%) in the whole series. Five of those 23 sporadic cases carried de novo mutations, 11 out of 23 of the mothers were proven carriers and, in the remaining seven families, it was not possible to determine carriership. Eleven of the 48 patients (23%) with severe haemophilia B developed inhibitors and all of them had deletions or nonsense mutations. Thus, 11 out of 37 (30%) patients with severe haemophilia B as a result of deletion/nonsense mutations developed inhibitors compared with 0 out of 11 patients with missense mutations. The ratio of male to female mutation rates was 5.3 and the overall mutation rate was 5.4 x 10(-6) per gamete per generation.

Factor IX gene haplotypes in Brazilian blacks and characterization of unusual DdeI alleles

Analysis of factor IX gene polymorphisms is considered the best approach for prenatal diagnosis and carrier detection of haemophilia B when the identification of the gene mutation is not possible. Studies involving factor IX gene polymorphisms in Black populations are scarce and essentially restricted to the North-American Black population whose composition is substantially different from that of the Brazilian and presumably other Black populations of South America. In this paper we report the analysis of eight factor IX gene polymorphisms in Brazilian Blacks: 5' BamHI, DdeI, intron 2 BamHI, XmnI, TaqI, TaqI, MspI, MnlI and HhaI. Characterization of the VNTR-like DdeI polymorphism revealed six different alleles: B, AB, A2B, A2B2, A3B and A5B, the last being described here for the first time. The 5' BamHI, DdeI, MspI and HhaI polymorphisms showed the highest heterozygosities (0.40-0.50) and are in linkage equilibrium with one another. 19 complete haplotypes could be identified in this population. Based on the results we propose a systematic strategy for carrier detection and prenatal diagnosis of haemophilia B in this population. The combined analysis of four polymorphisms (5' BamHI, HhaI, MspI and DdeI) provided an informative genetic marker in 85% of the females. The use of all eight polymorphisms allows information in 95% of females. Additionally, differences in gene frequencies and haplotype distribution suggest dissimilarities in factor IX gene polymorphisms between the Brazilian and the North-American Black populations.

Carrier detection and prenatal diagnosis of hemophilia B with more advanced techniques

We used the PCR to amplify three polymorphic regions of Factor IX gene on 35 Italian families: DdeI intron 1, Mn1I exon f, and the polymorphism HhaI located 8 kb at the 3' end of FIX gene. We analyzed the Mn1I and HhaI markers on DGGE and DdeI polymorphism on agarose gel. We reached an informativity of 78% and we found one mutation at codon 145 (exon f) during the screening for Mn1I polymorphism. Furthermore, we performed 16 prenatal diagnoses on chorionic villus samples; five were female and 11 male. Four were uninformative three healthy and one affected male fetus were recognized by PCR techniques, two healthy and one affected fetus by Southern analysis. In three pregnant women examined for the first time during pregnancy, the PCR technique allowed us to perform a rapid diagnosis of noncarrier status, avoiding the fetal sampling procedures.

Carrier detection and feasibility of prenatal diagnosis of hemophilia B by multiplex polymerase chain reaction

Since direct diagnosis based on detection of factor IX mutations by direct sequencing is currently performed in a few laboratories only, restriction fragment length polymorphisms are still useful for carrier detection and prenatal diagnosis of hemophilia B. We analyzed 29 women from 20 families at risk of hemophilia B with three intragenic (MnlI, DdeI, TaqI) and two extragenic (HhaI, BamHI) restriction fragment length polymorphisms, all by the polymerase chain reaction. This analysis confirmed 10 possible carriers and excluded 16 as carriers. The diagnosis was made in 17 of the 20 families (85%). The combination of three polymorphisms indicated that MnlI/DdeI/HhaI and TaqI/DdeI/HhaI were the most informative (15/20 families, 75% and 14/20 families, 70%). For carrier detection with the most useful polymorphism combination (TaqI/DdeI/HhaI) we devised a multiplex polymerase chain reaction that uses two or three sets of primers, allowing carrier diagnosis in one step with 99% reliability. Our results indicate that the combination of five restriction fragment length polymorphisms makes carrier detection and prenatal diagnosis possible for 85% of families at risk of hemophilia B, with 99% reliability. With multiplex polymerase chain reaction such diagnoses can be obtained faster.

Origin of mutation in sporadic cases of haemophilia-B

Of the 45 haemophilia-B patients registered at the haemophilia centre in Malmö, Sweden, 24 are the sole members of their families to be affected, and in 13 of these 24 cases, ascendant relatives are available for study. Detection of the gene defect showed the mutation to be de novo in the proband in 3 of these 13 cases, and inherited from a carrier mother in the remaining 10 cases. All 10 carrier mothers were shown to have de novo mutations, as the patients' grandfathers were phenotypically and/or haematologically normal, and the grandmothers were non-carriers. Seven restriction fragment length polymorphisms (RFLPs) of the factor IX gene were used to determine whether the de novo mutations of the 10 carrier mothers were of paternal or maternal origin. In 6/10 cases, the RFLP patterns were informative, and indicated the mutation to be of paternal origin.

The contribution of DNA analysis to carrier detection and prenatal diagnosis of hemophilia A and B

Developments in DNA technology have provided a novel means of carrier detection and prenatal diagnosis of hemophilia A and B. The collection of a large set of data has enabled us to evaluate the present feasibility and reliability of a diagnosis at the gene level and its contribution to methods already available. Since 1984, 533 potential and obligate carriers belonging to 170 families with hemophilia have been referred to us. By the combined use of pedigree analysis, coagulation assays, and DNA (RFLP) analysis, certainty about the carrier status has been markedly increased for the potential carriers. Although RFLP analysis revealed the possible origin of the mutation in many families with an isolated patient, uncertainty remained for quite a number of their female relatives because of the possible occurrence of germline mosaicism. Forty-one women requested prenatal diagnosis during one or more pregnancies. The short time interval between pregnancies, even after abortion of an affected fetus, proved that first-trimester prenatal diagnosis has become an acceptable option for women at risk. Recently, efficient methods for direct identification of mutations have been developed, and they may allow a definite diagnosis for all families with hemophilia in the near future.

Moderate haemophilia B in a female carrier caused by preferential inactivation of the paternal X chromosome

The case of a female with moderate haemophilia B is reported. She is the only affected member of her family, and factor IX RFLP analysis shows her to have inherited no maternal markers for polymorphisms located in the first intron and 8 Kb 3' of the polyadenylation signal (DdeI and HhaI, respectively). This clearly indicates a deletion involving at least the last 7 exons of the factor IX gene. Her other factor IX gene inherited from her healthy father is normal as her son is also healthy. This suggests the patient's haemophilia to be due to gross bias in the proportion of factor IX-producing cells with an inactive paternal X chromosome. Methylation studies on the 5' region of the PGK gene show that virtually all the patient's lymphocytes carry a hypermethylated and presumably an inactive paternal X chromosome. The reason for this bias in the activity of her two X chromosomes is not clear, as no chromosomal alterations were found.

Restriction fragment length polymorphisms associated with the factor VIII and factor IX genes in Polynesians

New Zealand Maoris (72 X chromosomes) have been compared with Pacific Island Polynesians (121 X chromosomes) and Caucasian New Zealanders (51 X chromosomes) as a control group to determine the allelic frequency of six RFLPs associated with the genes for two X linked diseases (haemophilia A and haemophilia B). RFLPs examined were BclI, XbaI, and BglI within the factor VIII gene, the factor VIII extragenic TaqI system, and the factor IX intragenic TaqI and XmnI sites. The information obtained facilitates the design of strategies for both carrier detection and prenatal diagnosis of haemophilia A within these groups. Strong linkage disequilibrium was observed between the factor VIII BclI and XbaI sites in Polynesians. Genetic counselling for Polynesians with haemophilia B continues, however, to rely on phenotypic diagnosis. The RFLP data from the two separate loci on the X chromosome in Polynesians show similarities with Chinese and Japanese populations, reinforcing theories of an early Polynesian ancestry originating in east Asia.

Mapping of a new RFLP marker RN1 (DXS369) close to the fragile site FRAXA on Xq27-q28

A new polymorphic DNA marker RN1, defining locus DXS369, was recently isolated. Using different somatic cell hybrids, RN1 was mapped between markers 4D-8 and U6.2. We have narrowed the localization of RN1 to the region between 4D-8 and FRAXA by genetic mapping in fragile X [fra(X)] families. Combined with information from other reports, the following order of loci on Xq27-q28 is suggested: cen-F9-(DXS105-DXS152)-DXS98-DXS369-FRAXA- DXS304-(DXS52-DXS15-F8)-tel. The locus DXS369 is closely linked to FRAXA, with a peak lodscore of 18.5 at a recombination fraction of 0.05. Therefore, RN1 is a useful probe for carrier detection and prenatal diagnosis in fra(X) families.

Common intragenic and extragenic polymorphisms of blood coagulation factors VIII and IX are different in Chinese and Caucasian populations

In order to examine the possibilities of carrier detection and prenatal diagnosis in hemophilia A and B in the Chinese region of Suzhou, we analyzed four different RFLPs within the factor IX gene and two intragenic RFLPs and one extragenic RFLP for the factor VIII gene. The results obtained show important differences between the Chinese and Caucasian populations. No polymorphism was found within the factor IX gene in the Chinese population and the informativity obtained for the factor VIII gene was quite different between the two populations for each RFLP studied.

Hemophilia B: diagnostic value of RFLP analysis in 19 of the 20 known Finnish families

With the aim of determining the usefulness of RFLP analysis in carrier detection and prenatal diagnosis, we studied all available members including 40 patients, 30 obligate carriers and 39 women at risk belonging to 19 out of a total of 20 Finnish hemophilia B families. The allele frequencies of the three intragenic polymorphisms studied (TaqI, XmnI and DdeI) did not differ significantly from those reported in other Caucasian populations. A considerable degree of linkage disequilibrium between the three polymorphisms was observed. Carriership evaluated in 39 females at risk led to exclusion in 14 while carriership was established in 5. The proportion of women who by pedigree analysis had a carriership risk between 10% and 90% could be reduced from 97% to 51% by RFLP analysis. Prenatal diagnosis using an intragenic polymorphism could potentially be offered to 69% of hemophilia carriers. DNAs from 19 unrelated patients were screened for mutations using a full-length cDNA probe, but no abnormal hybridization patterns were observed. Our results indicate that RFLP segregation analysis provides a useful method of carrier detection and prenatal diagnosis in hemophilia B.

New polymorphic DNA marker close to the fragile site FRAXA

DNA from a human-hamster hybrid cell line, 908-K1B17, containing a small terminal portion of the long arm of the human X chromosome as well as the pericentric region of 19q was used as starting material for the isolation of an X-chromosome-specific DNA segment, RN1 (DXS369), which identifies a XmnI RFLP. Linkage analysis in fragile X families resulted in a maximum lod score of 15.3 at a recombination fraction of 0.05 between RN1 and fra(X). Analysis of recombinations around the fra(X) and distal to DXS105. Analysis of the marker content of hybrid cell line 908K1B17 suggests the localization of RN1 between DXS98 and fra(X). Heterozygosity of DXS369 is approximately 50%, which extends the diagnostic potential of RFLP analysis in fragile X families significantly.

Carrier detection for hemophilia B: evaluation of multiple polymorphic sites

DNA analysis was performed in families with hemophilia B. Restriction fragment length polymorphisms (RFLPs) produced by endonucleases Taql, Xmnl, and Ddel were studied by two factor IX genomic probes, F9(VIII) and F9(XIII). Fifty-seven subjects from ten families were investigated; of them, 31 were carriers (11 obligate and 20 potential). Of the potential carriers, ten displayed laboratory features allowing for a phenotypic diagnosis of heterozygosity. Segregation analysis of the markers was informative in 19/20 potential carriers, which belong to nine of the ten studied families. Among the potential carriers, Taql allowed the carriership assessment in 15 (78.9%), Xmnl in 15 (94.7%), and Ddel in two (10.4%). Diagnosis was not possible in one family since a homozygosity in the key individuals with all the employed enzymes (Taql, Xmnl, Ddel, + BamHI) was found. Hemophilia B syndrome in two families likely results from a new mutation. In one family, a first-trimester prenatal diagnosis was performed. The use of RFLP analysis allowed us to improve genetic counseling as compared with the phenotypic evaluation by clotting factor assays. Indeed, evaluation of RFLP increased by 26% the carriership assessment of the potential carriers of the hemophilia B trait.

Diagnosis of haemophilia B using the polymerase chain reaction

The polymerase chain reaction (PCR) was used to amplify specific DNA sequences within the factor IX gene of haemophilia B patients and their relatives. Three of the amplified fragments contain polymorphic sites, which can be used as markers in segregation analyses. These restriction fragment length polymorphisms (RFLPs) were until recently detected by Southern blotting after digestion with the restriction enzymes Taq I, Dde I and Xmn I. All three RFLP's are located in introns of the factor IX gene and together are informative in approximately 70% of all cases. Each of the polymorphisms was successfully used in carrier detection studies after amplification of the relevant fragments. This method is also suitable for rapid antenatal diagnosis. Additionally we were able to amplify all eight exons of the factor IX gene including the splice junctions and a part of the 5'-region. Large deletions or insertions can be detected without further analysis. Several possibilities for the rapid detection of point mutations after DNA amplification have been described recently. The complete amplification of all functional parts of the Factor IX gene in combination with these new techniques should enable us to detect the majority of mutations leading to haemophilia B.

Detection of polymorphisms at cytosine phosphoguanadine dinucleotides and diagnosis of haemophilia B carriers

The polymerase chain reaction procedure (PCR) was used to detect a polymorphic Hha I site adjacent to the factor IX locus in a panel of 33 phenotypically normal caucasian individuals. This technique was also applied to a haemophilia B family pedigree. The Hha I polymorphic site was located 8 kb 3' to the factor IX gene, and the proportion of female subjects expected to be heterozygous at this site was 0.48. The Hha I locus was in linkage equilibrium with the other polymorphic loci on the factor IX gene. These findings, besides increasing the proportion of caucasian individuals whose haemophilia B carrier state can be diagnosed from 79% to 89%, demonstrate this widely applicable use of PCR for the detection of DNA polymorphism at cytosine phosphoguanadine dinucleotides irrespective of the methylation status.

Identification of a CpG mutation in the coagulation factor-IX gene by analysis of amplified DNA sequences

In a family with no previous bleeding history, the sister of a single, severely affected haemophilia B patient requested carrier detection and prenatal diagnosis. In Southern blots, using Taq I digested DNA and a factor-IX cDNA probe, a normal invariant band at 1.6 kb was missing in the haemophiliac suggesting the loss of the Taq I site at the 5' end of exon h. A 162 bp sequence which includes the suspected mutant region was amplified by the polymerase chain reaction in each DNA. Two oligonucleotide probes were synthesized and differed by only one base pair which substituted a T for C in the normal Taq I recognition sequence. The amplified DNA was dot-blotted and hybridized with the labelled probes. The altered sequence hybridized to DNA from the affected individual, his sister and her fetus and not to DNA from the normals. The mutation, involving the haemophiliac, his mother, his sister and her fetus, transforms a CGA codon that encodes for arginine in the catalytic domain of the protein into a UGA stop codon.

Improved DNA markers for efficient analysis of fragile X families

We report the characteristics of two new probes that detect BclI RFLPs useful for analysis of fragile X families. With these two probes and a single blot, 34% of women are heterozygous both for the proximal marker DXS105 (closer to the fragile X locus than the factor IX gene) and for the distal markers DXS52 or the factor VIII gene. Combined with the analysis of previously described polymorphic markers, it is possible to have a majority of families fully informative for flanking markers using a limited number of probes and restriction digests.

X-linked lymphoproliferative disease: linkage studies using DNA probes

Linkage studies have been carried out with 28 X-linked polymorphic probes to try to locate the gene for X-linked lymphoproliferative disease (XLP). DNA from three families has been analysed, including three affected boys among 21 family members. None of the probes tested has been found to be linked to XLP. However, the data are recorded for the use of other workers on this rare disease.

Carrier detection in the hemophilias

The subject of carrier detection in the hemophilias has received new impetus in the past several years. Treatment complications arising from clotting factor concentrates have become more evident and earlier prenatal diagnosis and new genetic markers for the clotting factor genes have focused interest on this area. Until now, carrier diagnosis has relied upon standard pedigree analysis and clotting factor assays. The results obtained using these methods are probabilistic, and the coagulation tests are unavoidably influenced by the effects of random X chromosome inactivation and the inherent variability of the methods involved. With the cloning and characterization of both factor IX and factor VIII genes, has come the capability of using gene analysis to diagnose the carrier state. This usually involves the detection of restriction fragment length polymorphisms (RFLPs) and their use as linked markers for the defective clotting factor gene. In hemophilia A, the combined use of three intragenic RFLPs and two closely linked, highly polymorphic extragenic markers will make carrier information available to approximately 90% of kindred. In hemophilia B, phenotypic analysis has been complicated by the more heterogeneous expression of the gene defect. To date, five intragenic and one closely linked RFLP have been reported, as well as two protein polymorphisms detectable by monoclonal antibody immunoassays. With the combined use of these genetic markers it is likely that accurate carrier assignment will be available to more than 80% of hemophilia B families.

A DNA marker closely linked to the factor IX (haemophilia B) gene

We have isolated a DNA segment, pX58dIIIc, from an X-chromosome library which identifies an SstI restriction fragment length polymorphism (RFLP) at locus DXS99. Linkage analysis in six informative families has shown that the DXS99 locus lies close to the factor IX gene (F9). No recombination was detected between these loci in 39 informative meioses (Z = 9.79, theta = 0.0). Therefore, DXS99 will be useful as a DNA marker for the assessment of carrier status in families with haemophilia B where intragenic markers are not informative. Heterozygosity at DXS99 is approximately 50% and, in conjunction with the RFLPs at F9, 90% of females at risk for being haemophilia B carriers should be diagnosed.

Hemophilia B (Christmas disease) variants and carrier detection analyzed by DNA probes

We have used two strategies to study 14 hemophilia B families from 11 kindreds for possible carrier detection and prenatal diagnosis. First, we sequentially used the Factor IX probes (sequentially with restriction enzymes Taq I, Xmn I, and Dde I), and the linked probes p45h (Taq I), p45d (Pst I), and 52a (Taq I) for restriction fragment length polymorphism (RFLP) analysis. Second, we searched for useful variant Taq I digestion fragments using the Factor IX complementary DNA. Two separate new Taq I variants in exon VIII were identified. Using both strategies, 11 of 14 families (from 9 of 11 kindreds) were informative for further studies. In five kindreds studied in detail, the carrier status of all 11 at risk females was determined and prenatal diagnosis could be offered to the offsprings of each of the six carriers identified. Thus, in this study, we have identified a higher proportion of informative families than has previously been reported.

Characterization of a set of X-linked sequences and of a panel of somatic cell hybrids useful for the regional mapping of the human X chromosome

We have characterized 19 DNA fragments originating from the human X chromosome. Most of them have been isolated from an X chromosome genomic library (Davies et al. 1981) using a systematic screening procedure. These DNA probes have been used to search for restriction fragment length polymorphisms (RFLP). The frequency of restriction polymorphisms (1 per 350 bp analysed) was lower than expected from data obtained with autosomal fragments. The various probes have been mapped within 12 subchromosomal regions using a panel of human-rodent hybrid cell lines. The validity of the panel was established by hybridization experiments performed with 27 X-specific DNA probes, which yielded information on the relative position of translocation breakpoints on the X chromosome. The DNAs from the various hybrid lines are blotted onto a reusable support which allows one to quickly map any new X-specific DNA fragment. The probes already isolated should be of use to map unbalanced X chromosome aberrations or to characterize new somatic cell hybrid lines. The probes which detect RFLPs define new genetic markers which will help to construct a detailed linkage map of the human X chromosome, and might also serve for the diagnosis of carriers or prenatal diagnosis.